Hybrid event bed character and distribution in the context of ancient deep‐lacustrine fan models

Hybrid event beds are texturally and compositionally‐diverse deposits preserved within deepwater settings. They are deposited by flows exhibiting ‘mixed behaviour’, forming complex successions of sandstone and mudstone, which are often challenging to predict. Hybrid event beds are documented in deep‐marine settings, where they have been thoroughly characterized, and are well‐known as effective fluid transmissibility barriers and baffles in reservoirs. By comparison, there are far‐fewer studies of hybrid event beds from deep‐lacustrine settings, where their character and distribution remains relatively under‐explored. In order to provide insights into these deposits, this study presents the detailed analysis of three‐dimensional seismic data, wireline logs and core from a series of ancient deep‐lacustrine fan systems in the North Falkland Basin. Results confirm that deep‐lacustrine hybrid event beds comprise the same idealized sequence of the ‘H1–H5’ divisions. However, in this study H3 ‘debrite’ units can be sub‐divided into ‘H3a–H3c’, based on: sharp or erosional intra‐H3 contacts, bulk lithology, mud‐content and discrete sedimentary textures. This study interprets the H3a–H3c sub‐units as the products of multiple flow components formed through significant rearward longitudinal flow transformation processes, during the emplacement of a single hybrid event bed. Hybrid event beds are observed within lobe fringes, where flow types, energies and transport mechanisms diversify as a result of flow transformation. The temporal context of hybrid event bed occurrences is considered in relation to stages of fan evolution, including: the Initiation; Growth (I); Growth (II); By‐pass; Abandonment; and Termination phases. Hybrid event beds are mainly found in either the initiation phase where flow interaction and erosion of initial substrates promoted mixed flow behaviour, or in the abandonment phase as facies belts retreated landward. The results of this study have important implications in terms of flow processes of hybrid event bed emplacement, in particular sub‐division of the H3 unit, as well as the prediction of hybrid event bed occurrence and character within ancient deep‐lacustrine fan settings, in general.

[1]  J. Peakall,et al.  Sole marks reveal deep-marine depositional process and environment: Implications for flow transformation and hybrid-event-bed models , 2021, Journal of Sedimentary Research.

[2]  Xinghe Yu,et al.  Bed type and flow mechanism of deep water sub-lacustrine fan fringe facies: an example from the Middle Permian Lucaogou Formation in Southern Junggar Basin of NW China , 2020, Petroleum Science.

[3]  Huaqing Liu,et al.  Sublacustrine gravity-induced deposits: The diversity of external geometries and origins , 2020 .

[4]  D. Dong,et al.  Thickening-upward cycles in deep-marine and deep-lacustrine turbidite lobes: examples from the Clare Basin and the Ordos Basin , 2020, Journal of Palaeogeography.

[5]  J. Baas,et al.  Mixed sand–mud bedforms produced by transient turbulent flows in the fringe of submarine fans: Indicators of flow transformation , 2020, Sedimentology.

[6]  F. Felletti,et al.  Origin of mud in turbidites and hybrid event beds: Insight from ponded mudstone caps of the Castagnola turbidite system (north‐west Italy) , 2020, Sedimentology.

[7]  A. Hussain,et al.  High‐resolution X‐ray fluorescence profiling of hybrid event beds: Implications for sediment gravity flow behaviour and deposit structure , 2020, Sedimentology.

[8]  F. Pohl,et al.  Entangled external and internal controls on submarine fan evolution: an experimental perspective , 2020, The Depositional Record.

[9]  S. Clarke,et al.  Clastic injectites, internal structures and flow regime during injection: The Sea Lion Injectite System, North Falkland Basin , 2019, Sedimentology.

[10]  K. Taylor,et al.  Transport and deposition of mud in deep‐water environments: Processes and stratigraphic implications , 2019, Sedimentology.

[11]  T. J. Dodd,et al.  Tectonostratigraphy and the petroleum systems in the Northern sector of the North Falkland Basin, South Atlantic , 2019, Marine and Petroleum Geology.

[12]  Keyu Liu,et al.  Genesis and depositional model of subaqueous sediment gravity-flow deposits in a lacustrine rift basin as exemplified by the Eocene Shahejie Formation in the Jiyang Depression, Eastern China , 2019, Marine and Petroleum Geology.

[13]  Xiaomin Zhu,et al.  An early Eocene subaqueous fan system in the steep slope of lacustrine rift basins, Dongying Depression, Bohai Bay Basin, China: Depositional character, evolution and geomorphology , 2019, Journal of Asian Earth Sciences.

[14]  D. Hodgson,et al.  Quantification of Basin-Floor Fan Pinchouts: Examples From the Karoo Basin, South Africa , 2019, Front. Earth Sci..

[15]  P. Burgess,et al.  A Big Fan of Signals? Exploring Autogenic and Allogenic Process and Product In a Numerical Stratigraphic Forward Model of Submarine-Fan Development , 2019, Journal of Sedimentary Research.

[16]  D. Hodgson,et al.  Topographic Controls On the Development of Contemporaneous but Contrasting Basin-Floor Depositional Architectures , 2018, Journal of Sedimentary Research.

[17]  J. Peakall,et al.  Deep-water channel-lobe transition zone dynamics: Processes and depositional architecture, an example from the Karoo Basin, South Africa , 2018 .

[18]  A. Piazza,et al.  Turbidites facies response to the morphological confinement of a foredeep (Cervarola Sandstones Formation, Miocene, northern Apennines, Italy) , 2018, Sedimentology.

[19]  T. J. Dodd,et al.  A depositional model for deep‐lacustrine, partially confined, turbidite fans: Early Cretaceous, North Falkland Basin , 2018, Sedimentology.

[20]  J. Godlewski,et al.  Integrated Dynamic Modelling of the Sea Lion Field , 2018, Day 2 Tue, June 12, 2018.

[21]  A. Imrie,et al.  An Integrated Formation Evaluation Approach To Characterize a Turbidite Fan Complex: Case Study, Falkland Islands , 2018 .

[22]  P. Haughton,et al.  Variable character and diverse origin of hybrid event beds in a sandy submarine fan system, Pennsylvanian Ross Sandstone Formation, western Ireland , 2018 .

[23]  F. Felletti,et al.  Hybrid event bed character and distribution linked to turbidite system sub‐environments: The North Apennine Gottero Sandstone (north‐west Italy) , 2018 .

[24]  D. Hodgson,et al.  Autogenic controls on hybrid bed distribution in submarine lobe complexes , 2017 .

[25]  Xiaomin Zhu,et al.  The occurrence and transformation of lacustrine sediment gravity flow related to depositional variation and paleoclimate in the Lower Cretaceous Prosopis Formation of the Bongor Basin, Chad , 2017 .

[26]  J. Eggenhuisen,et al.  The stratigraphic record and processes of turbidity current transformation across deep‐marine lobes , 2017 .

[27]  W. McCaffrey,et al.  Hybrid event beds dominated by transitional‐flow facies: character, distribution and significance in the Maastrichtian Springar Formation, north‐west Vøring Basin, Norwegian Sea , 2017 .

[28]  D. Hodgson,et al.  Frontal and Lateral Submarine Lobe Fringes: Comparing Sedimentary Facies, Architecture and Flow Processes , 2017 .

[29]  Kristin W. Porten,et al.  A Sedimentological Process-Based Approach To Depositional Reservoir Quality of Deep-Marine Sandstones: An Example From the Springar Formation, Northwestern Vøring Basin, Norwegian Sea , 2016 .

[30]  B. T. N. Phuong,et al.  Density-Flow Deposition In A Fresh-Water Lacustrine Rift Basin, Paleogene Bach Long Vi Graben, Vietnam , 2016 .

[31]  F. Felletti,et al.  Hybrid Event Beds Generated By Local Substrate Delamination On A Confined-Basin Floor , 2016 .

[32]  F. Felletti,et al.  Short length-scale variability of hybrid event beds and its applied significance , 2015 .

[33]  J. Eggenhuisen,et al.  Deep-Water Sediment Bypass , 2015 .

[34]  J. Underhill,et al.  Role of rift transection and punctuated subsidence in the development of the North Falkland Basin , 2015 .

[35]  C. Booth,et al.  Sea Lion Field, North Falkland Basin: seismic inversion and quantitative interpretation , 2015 .

[36]  R. Bunt The use of seismic attributes for fan and reservoir definition in the Sea Lion Field, North Falkland Basin , 2015 .

[37]  L. S. Williams Sedimentology of the Lower Cretaceous reservoirs of the Sea Lion Field, North Falkland Basin , 2015 .

[38]  F. Macaulay Sea Lion Field discovery and appraisal: a turning point for the North Falkland Basin , 2015 .

[39]  F. Felletti,et al.  Influence of flow containment and substrate entrainment upon sandy hybrid event beds containing a co-genetic mud-clast-rich division , 2015 .

[40]  R. Wynn,et al.  On how thin submarine flows transported large volumes of sand for hundreds of kilometres across a flat basin plain without eroding the sea floor , 2014 .

[41]  R. Arnott,et al.  Matrix‐rich and associated matrix‐poor sandstones: Avulsion splays in slope and basin‐floor strata , 2014 .

[42]  Rob Simm,et al.  Seismic Amplitude: An Interpreter's Handbook , 2014 .

[43]  P. Haughton,et al.  Rheological Complexity In Sediment Gravity Flows Forced To Decelerate Against A Confining Slope, Braux, SE France , 2014 .

[44]  P. Talling Hybrid submarine flows comprising turbidity current and cohesive debris flow: Deposits, theoretical and experimental analyses, and generalized models , 2013 .

[45]  D. Nummedal,et al.  Lacustrine Sandstone Reservoirs and Hydrocarbon Systems , 2012 .

[46]  I. Kane,et al.  Submarine transitional flow deposits in the Paleogene Gulf of Mexico , 2012 .

[47]  R. Wynn,et al.  Facies architecture of individual basin‐plain turbidites: Comparison with existing models and implications for flow processes , 2012 .

[48]  J. Eggenhuisen,et al.  Concentration-Dependent Flow Stratification In Experimental High-Density Turbidity Currents and Their Relevance To Turbidite Facies Models , 2012 .

[49]  J. Best,et al.  Depositional processes, bedform development and hybrid bed formation in rapidly decelerated cohesive (mud–sand) sediment flows , 2011 .

[50]  S. Luthi,et al.  Flow–Deposit Interaction in Submarine Lobes: Insights from Outcrop Observations and Realizations of a Process-Based Numerical Model , 2010 .

[51]  D. Hodgson,et al.  Evolution, architecture and hierarchy of distributary deep‐water deposits: a high‐resolution outcrop investigation from the Permian Karoo Basin, South Africa , 2009 .

[52]  P. Haughton,et al.  Character and distribution of hybrid sediment gravity flow deposits from the outer Forties Fan, Palaeocene Central North Sea, UKCS , 2009 .

[53]  A. Gardiner,et al.  Prediction of hydrocarbon recovery from turbidite sandstones with linked-debrite facies: Numerical flow-simulation studies , 2009 .

[54]  P. Haughton,et al.  Hybrid sediment gravity flow deposits – Classification, origin and significance , 2009 .

[55]  E. Sumner,et al.  Deposits of flows transitional between turbidity current and debris flow , 2009 .

[56]  Jeff Peakall,et al.  A Phase Diagram for Turbulent, Transitional, and Laminar Clay Suspension Flows , 2009 .

[57]  E. Sumner,et al.  Deposit Structure and Processes of Sand Deposition from Decelerating Sediment Suspensions , 2008 .

[58]  P. Haughton,et al.  Development of Rheological Heterogeneity in Clay-Rich High-Density Turbidity Currents: Aptian Britannia Sandstone Member, U.K. Continental Shelf , 2008 .

[59]  J. Merritt,et al.  EXPLORING FOR FAN AND DELTA SANDSTONES IN THE OFFSHORE FALKLANDS BASINS , 2006 .

[60]  P. Talling,et al.  Anatomy of turbidites and linked debrites based on long distance (120 × 30 km) bed correlation, Marnoso Arenacea Formation, Northern Apennines, Italy , 2006 .

[61]  N. Drinkwater,et al.  Stratigraphic Evolution of Fine-Grained Submarine Fan Systems, Tanqua Depocenter, Karoo Basin, South Africa , 2006 .

[62]  J. Baas Conditions for formation of massive turbiditic sandstones by primary depositional processes , 2004 .

[63]  P. Haughton,et al.  ‘Linked’ debrites in sand‐rich turbidite systems – origin and significance , 2003 .

[64]  Y. Sohn,et al.  Transition from debris flow to hyperconcentrated flow in a submarine channel (the Cretaceous Cerro Toro Formation, southern Chile) , 2002 .

[65]  R. Wynn,et al.  Characterization and recognition of deep-water channel-lobe transition zones , 2002 .

[66]  B. Kneller,et al.  Process controls on the development of stratigraphic trap potential on the margins of confined turbidite systems and aids to reservoir evaluation , 2001 .

[67]  J. Alexander,et al.  The physical character of subaqueous sedimentary density flows and their deposits , 2001 .

[68]  P. Richards,et al.  POST‐DRILLING ANALYSIS OF THE NORTH FALKLAND BASIN— PART 1: TECTONO‐STRATIGRAPHIC FRAMEWORK , 2000 .

[69]  D. Lowe,et al.  Slurry‐flow deposits in the Britannia Formation (Lower Cretaceous), North Sea: a new perspective on the turbidity current and debris flow problem , 2000 .

[70]  D. Stow,et al.  Hemipelagites: processes, facies and model , 1998, Geological Society, London, Special Publications.

[71]  Y. Sohn On traction-carpet sedimentation , 1997 .

[72]  P. Richards,et al.  GEOLOGY OF THE NORTH FALKLAND BASIN , 1997 .

[73]  R. Gatliff,et al.  PETROLEUM POTENTIAL OF THE FALKLAND ISLANDS OFFSHORE AREA , 1996 .

[74]  B. Horton,et al.  Sedimentology of a lacustrine fan-delta system, Miocene Horse Camp Formation, Nevada, USA , 1996 .

[75]  J. Williamson,et al.  The geological evolution of the Falkland Islands continental shelf , 1996, Geological Society, London, Special Publications.

[76]  W. Nemec,et al.  Large floating clasts in turbidites: a mechanism for their emplacement , 1988 .

[77]  W. Dean,et al.  Lacustrine varve formation through time , 1988 .

[78]  Thomas C. Pierson,et al.  A rheologic classification of subaerial sediment-water flows , 1987 .

[79]  W. Normark,et al.  Comparing Examples of Modern and Ancient Turbidite Systems: Problems and Concepts , 1987 .

[80]  J. Allen Parallel lamination developed from upper-stage plane beds: A model based on the larger coherent structures of the turbulent boundary layer , 1984 .

[81]  K. Pickering Transitional submarine fan deposits from the late Precambrian Kongsfjord Formats submarine fan, NE Finnmark, N. Norway , 1983 .

[82]  D. Lowe Sediment Gravity Flows: II Depositional Models with Special Reference to the Deposits of High-Density Turbidity Currents , 1982 .

[83]  T. Pierson,et al.  Dominant particle support mechanisms in debris flows at Mt Thomas, New Zealand, and implications for flow mobility , 1981 .

[84]  F. Lucchi,et al.  Basin‐wide turbidites in a Miocene, over‐supplied deep‐sea plain: a geometrical analysis , 1980 .

[85]  D. Lowe Sediment Gravity Flows: Their Classification and Some Problems of Application to Natural Flows and Deposits , 1979 .

[86]  J. R. Allen,et al.  Sedimentary Structures , 1965, Nature.

[87]  R. Walker,et al.  THE ORIGIN AND SIGNIFICANCE OF THE INTERNAL SEDIMENTARY STRUCTURES OF TURBIDITES , 1965 .